Sapphire: cryst. Al2O3 Insulin Chapter 3: The Structure of ...
Transcript of Sapphire: cryst. Al2O3 Insulin Chapter 3: The Structure of ...
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Chapter 3
Chapter 3: The Structure of Crystalline Solids
Crystal:
a solid composed of atoms, ions, or molecules arranged in a patternthat is repeated in three dimensions
A material in which atoms are situated in a repeating or periodic array over large atomic distances
Sapphire: cryst. Al2O3 Insulin
Chapter 3
3.1 Classification
• Crystalline materials- atoms(ions or molecules) in repeating 3D pattern (called a lattice)- long-range order; ex.: NaCl,
• Amorphous (noncrystalline) materials- Short range order, not periodic; ex.: liquid water, glass
• Fractals- Long-range order, symmetry, but not repeating
• Liquid crystals- long range order of one type; disorder of another- Nematic and smectic
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Chapter 3
Translational SymmetryConsider perfect ideal solid
The translational group represented by space lattice or Bravais net
Lattice sites defined by:
l = l1 a1 + l2 a2 + l3 a3
O a1
a2
l
The actual definition of a unit cell is to some extent arbitrary
NB: atoms do not necessarily coincide with space lattice
Chapter 3
Space lattice
Positions of atoms in crystals can be defined by referring the atoms to the point of intersection with 3D coordinate system
+ X- X
+ Z
- Z
+ Y
- Y
000
Such network is called space or crystal lattice
In ideal crystal the grouping of lattice points about any given point are identical with the grouping about any other lattice point in the crystal lattice
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Unit cell
(0, 0, 0)
a = a
a
b
c The size and shape of the unit cell can be described by three lattice vectors: a, b, cor the axial lengths a, b, and c and interaxialangles α, β, γγ
βα
NB!!!: atoms do not necessarily coincide with lattice points
Chapter 3
How to choose unit cell?
Larger than needed
Unit cell: a convenient repeating unit of a crystal lattice; the axial lengths and axial angles are the lattice constants of the unit cell
Wigner –Seitz cell
Wigner – Seitz Cell : place the symmetry centre in the centre of the cell; draw the perpendicular bisector planes of the translation vectors from the chosen centre to the nearest equivalent lattice site
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Crystal systems (7)
symm
etry
crystallographic point group – set of symmetry operations, (ex.: rotations or reflections), that leave a point fixed while moving each atom of the crystal to the position of an atom of the same kind
Chapter 3
14 Bravais Lattices
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Chapter 3
230 lattices or spacegroups
a ≠ b ≠ c; α ≠ β ≠ γ ≠ 90o
Lowest in symmetry #1:
Chapter 3
Even higher symmetry structure
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Chapter 3
Metallic crystal structures (will talk about metal oxides later)
• >90% of elemental metals crystallize upon solidification into 3 densely packed crystal structures:
Body-centered cubic (bcc)
ex.: Fe, W, Cr
Face-centered cubic (fcc)
ex.: Cu, Ag, Au
Hexagonal close-packed (hcp)
ex.: Zr, Ti, Zn
Chapter 3
Important to know:
• Distance between atoms (d)- in terms of a
• Number of atoms in the unit cell- each corner atoms shared by 8 cells: 1/8- each face atom shared by 2 cells: ½- each edge atom shared by 4 cells: 1/4
• Coordination number- Number of nearest neighbours (n.n.); for metals all equivalent
• Atomic Packing Factor (APF)APF = Volume of atoms in unit cell / Volume of unit cell (a3)
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Chapter 3
Coordination number
The number of atoms that surround a central atom in a solid is called coordination number
C.N. = 8Corners of cube
C.N. = 6Corners of octahedron
C.N. = 4Corners of tetrahedron
C.N. = 3Corners of triangle
Chapter 3
Body-Centered Cubic (bcc)
a
Distance between atoms:
Atoms/cell:
Coordination number:
Atomic Packing Factor (APF):
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Chapter 3
Face-Centered Cubic (fcc)
Distance between atoms:
Atoms/cell:
Coordination number:
Atomic Packing Factor (APF):
Chapter 3
Hexagonal close-packed (hcp)
Distance between atoms: a and c
Atoms/cell:
Coordination number:
Atomic Packing Factor (APF):
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Chapter 3
Density calculations
• Calculate theoretical density of gold (Au), if the molar density is given: w = 0.1970 kg/mol; and a(Au)=0.408nm
Chapter 3
3.4 Atom coordinates in the cubic unit cell
+ Y- Y
+ Z
- Z+ X
- X
000a
(0, 0, 0)
(1, 0, 0)
(0, 1, 0)
(0, 0, 1)
(1, 1, 1)
(1, 1, 0)
(1, 0, 1)
(0, 1, 1)
(½, ½, ½)
bcc
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Chapter 3
Face-Centered Cubic (fcc)
8 Cu 6 Cu
(0, 0, 0) (½, ½, 0)
(1, 0, 0) (0, ½, ½)
(0, 1, 0) (½, 0, ½)
(0, 0, 1) (½, ½, 1)
(1, 1, 1) (1, ½, ½)
(1, 1, 0) (½, 0, ½)
(1, 0, 1)
(0, 1, 1)
Chapter 3
Sodium Chloride (NaCl)
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Chapter 3
Strontium titanate (SrxTiyOz)
Ti O
Sr
Chapter 3
3.5 Directions in cubic unit cell
+ Y- Y
+ Z
- Z+ X
- X
0001 2
-1-2
1
2
[2, 0, 0]
=
[1, 0, 0]
The crystallographic direction indices [u, v, w] - the vectors of the direction resolved along each of the coordinate axes and reduced to the smallest integers
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Chapter 3
Examples:
Chapter 3
Crystallographically equivalent
• Parallel direction vectors have the same direction indices:ex.: determine the direction indices of the cubic direction shown
• Directions are crystallographically equivalent if the atom spacing along each directions are the same
ex.: [100], [010], [001], [-100], [0-10], [00-1] = <100>
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Chapter 3
3.6 Miller indices for crystallographic planes in cubic unit cells
• Miller indices of a crystal plane are the reciprocals of the fractional intercepts that the plane makes with the crystallographic x, y, and z axesMost important crystallographic planes: (100), (110), (111)
(100) intercepts:
1, ∞, ∞
Chapter 3
Atomic Packing in Different Planes
• bcc (100) (110) (111)
• fcc (100) (110) (111)
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Chapter 3
fcc crystallographic planesCu (100)
Chapter 3
fcc crystallographic planes
Cu (110)
Anisotropy of properties in two directions
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Chapter 3
fcc crystallographic planes
Cu (111)
3 fold symmetry
Chapter 3
STM (Scanning tunneling microscopy)
Cu (100) Cu (111)
Custom Low Temperature UHV STM image of atomic resolution pattern on Cu(111). Image taken at 4.2K.
Atomically resolved STM of Cu(100)
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Chapter 3
Crystallographic planes
• Single plane (h k l)
• Notation: planes of a family {h k l}(100); (010); (001); … ⇒{100}
• Only for cubic systems: the direction indices of a direction perpendicular to a crystal plane have the same Miller indices as a plane
• Interplanar spacing dhkl:
222 lkhadhkl
++=
Chapter 3
3.7 Planes in hexagonal crystals
4 coordinate axes (a1, a2, a3, and c) of the HCP structure (instead of 3)
Miller-Bravais indices - (h k i l) – based on 4 axes coordinate system
a1, a2, and a3 are 120o apart: h k i
c axis is 90o: l
3 indices (rarely used):
h + k = - I
(h k i l) ⇒ (h k l)
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Chapter 3
Basal and Prizm Planes
Basal planes;
a1 = ∞; a2 = ∞; a3 = ∞; c = 1
⇒ (0 0 0 1)
Prizm planes: ABCD
a1 = +1; a2 = ∞; a3 = -1; c = ∞
⇒ (1 0 -1 0)
Chapter 3
Directions in hexagonal crystals
+ a2
+ c
- c+ a1
- a1
0001 2
-1-2
1
2
[u, v, t, w] or
[u, v, w] u + v = -t
+ a3
- a2
- a3
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Chapter 3
Principle directions in hcp
Chapter 3
3.8 Comparison of crystal structures
FCC and HCP metal crystal structures
• (111) planes of fcc have the same arrangement as (0001) plane of hcp crystal
• 3D structures are not identical: stacking has to be considered
A
void a
void b
B Bb
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Chapter 3
FCC and HCP crystal structures
A A
fcc
B plane placed in a voids of plane A
Next plane placed in a voids of plane B, making a new C plane
Stacking: ABCABC…
B B
hcp
B plane placed in a voids of plane A
Next plane placed in a voids of plane B, making a new A plane
Stacking: ABAB…
void bvoid a
AC
Chapter 3
3.9 Volume, planar, and linear density unit cell calculations
cellunitvolumecellunitmassmetalofdensityVolume v _/
_/___ == ρ
Volume density of a metal can be obtained by using the hard-sphere atomic model for the crystal structure unit cell
Q.: Copper has an fcc crystal structure and an atomic radius of 0.1278nm. Assuming the Cu atoms to be hard spheres that touch each other along the face diagonal of the fcc unit cell, calculate a theoretical value for the density of Cu in kg/m3.
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Chapter 3
3.10 Allotropy and polymorphism (=..?)
Allotropy – the ability of element to exist in two or more crystalline structures
Fe: bcc ⇒ fcc ⇒ bcc
In case of compound it is called polymorphism
Carbon allotropic forms: ?
1. diamond2. graphite 3. fullerene or buckyballs4. nanotubes or buckysheets
Chapter 3
Carbon and its allotropes
Diamond• Cubic structure
(0, 0, 0) (1/2, 1/2, 0) (1/4, 1/4, 1/4)• Covalently bonded sp3 orbitals• Isotropic• Stiffest, hardest (?) and least
compressible• High thermal conductivity• But… no electrical conductivity
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Chapter 3
Graphite
Graphite• hexagonal structure• covalently bonded sp2 orbitals and
weak secondary bonds between planes
• anisotropic• High thermal and electrical conductivity(in plane)• Bad thermal and electrical conductivity(between plane, along c axis)
Chapter 3
Fullerenes (Buckyballs)
Discovered in 1985 by Harry Kroto and Richard Smalley while blasting graphite with a laser (C30 to C100)
• 12 pentagons and 20 hexagons• crystallize in fcc structure• isotropic• bonding: covalent and van der Waals forces
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Chapter 3
Carbon nanotubes
• hexagonal• properties depend on the structure• more later…
Chapter 3
Carbon Nanotubes
The structure can be specified by vector (n, m)which defines how the graphene sheet is rolled up
A nanotube with the indices (6,3): the sheet is rolled up so that the atom (0,0) is superimposed on the one labeled (6,3)
m = 0 for all zig-zag tubes, while n = m for all armchair tubes
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Chapter 3
• Unit cells, crystal systems and lattices• Atomic coordinates and number of atoms in the unit cell• Crystallographic directions and crystal planes • Coordination numbers
• Finding distances between atoms and planes, and characteristic angles
• In order to find all this parameters: X-ray diffraction, electron microscopy (later)
Summary
Chapter 3
Problems
3.1. Molybdenum is bcc and has an atomic radius of 0.14nm. Calculate a value for its lattice constant a in nanometers.
3.2. Figure below illustrates unit cell of diamond crystal structure. (a) How many carbon atoms are there per unit cell?(b) What is the coordination number for each carbon atoms? (C.N is the number of equidistant nearest
neighbors to an atom in a crystal structure)
3.3. Draw direction vectors in unit cubes for the following directions: (a) [111], (b) [1-1-1], (c) [-12-1]; (d) [-1-13]
3.4. Define the Miller indices of the cubic crystal plane that intersects the following position coordinates: (a)1/2, 0, 1/2); (0, 0, 1); (1, 1, 1); (b) (0, 0, 1/2); (1, 0, 0); (1/2, 1/4, 0)
3.5. Draw in unit cubes the crystal planes that have the following Miller indices:(a) (1-1-1); (b) (10-2), (c) (1-21), (d) (21-3)
3.6 Allotropic phase change. Iron is observed to undergo a transformation from bcc to fcc cubic structure at 9210C. Assuming thatin each case the atoms behave as hard spheres and that the size ofthese spheres is not affected by the transformation, determine the
percentage change in volume that occurs.